Abstract
It has been known that a non-perfect fluid that accounts for dissipative viscous effects can evade a highly anisotropic chaotic mixmaster approach to a singularity. Viscosity is often simply parameterised in this context, so it remains unclear whether isotropisation can really occur in physically motivated contexts. We present a few examples of microphysical manifestations of viscosity in fluids that interact either gravitationally or, for a scalar field for instance, through a self-coupling term in the potential. In each case, we derive the viscosity coefficient and comment on the applicability of the approximations involved when dealing with dissipative non-perfect fluids. Upon embedding the fluids in a cosmological context, we then show the extent to which these models allow for isotropisation of the universe in the approach to a singularity. We first do this in the context of expansion anisotropy only, i.e., in the case of a Bianchi type-I universe. We then include anisotropic 3-curvature modelled by the Bianchi type-IX metric. It is found that a self-interacting scalar field at finite temperature allows for efficient isotropisation, whether in a Bianchi type-I or type-IX spacetime, although the model is not tractable all the way to a singularity. Mixmaster chaotic behaviour, which is well known to arise in anisotropic models including anisotropic 3-curvature, is found to be suppressed in the latter case as well. We find that the only model permitting an isotropic singularity is that of a dense gas of black holes.
Highlights
While the currently observable universe is isotropic to a very high degree, this is not a generic feature of spacetimes near singularities—rather the opposite
We present a few examples of microphysical manifestations of viscosity in fluids that interact either gravitationally or, for a scalar field for instance, through a self-coupling term in the potential
The expense occurs by hypothesizing some possible new physics at the bounce, which causes the universe to reexpand after an initial phase of contraction
Summary
While the currently observable universe is isotropic to a very high degree, this is not a generic feature of spacetimes near singularities—rather the opposite. Upon introducing a dissipative term in the energy-momentum tensor such as πab, one has to be aware that the fluid may deviate from its thermodynamic equilibrium, and the relaxation time τ to the equilibrium state (a.k.a. the collision time or Maxwell time) may generally be nonzero In such a case, there is no closed analytic expression for these viscous anisotropic pressures. Given a model for which one can compute the viscosity thanks to Eq (17), the above lower and upper bounds essentially tell us the regime of validity of that expression in terms of the size of the fluid’s mean free path This shall be the basis of our consistency checks throughout this work
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